gpamela/gpfield/inter_B.F

*************************************************************************
*     
*     Subroutine inter_B.f (from tracker software analysis)
*     
*     it computes the magnetic field in a chosen point x,y,z inside or 
*     outside the magnetic cavity, using a trilinear interpolation of
*     B field measurements (read before by means of ./read_B.f)
*     if the point falls outside the interpolation volume, set the field to 0
*     
*     needs:
*     - ../common/common_B_inner.f common file for the inner magnetic field map
*     - ./inter_B_inner.f common file for the inner magnetic field map
*     
*     to be called after ./read_B.f (magnetic field map reading subroutine)
*     
*     input: coordinates in m
*     output: magnetic field in T
*     
*************************************************************************

      subroutine inter_B(x,y,z,res) !coordinates in m, magnetic field in T
      IMPLICIT DOUBLE PRECISION (A-H,O-Z)
#include "gpfield.inc"

c------------------------------------------------------------------------
c     
c     local variables
c     
c------------------------------------------------------------------------

      real*8 x,y,z              !point of interest
      real*8 res(3)             !interpolated B components: res = (Bx, By, Bz)

      real*8 zl,zu
      real*8 resu(3),resl(3)
c------------------------------------------------------------------------
c     
c     set the field outside the interpolation volume to be 0
c     
c------------------------------------------------------------------------

      do ip=1,3
        res(ip)=0.
      enddo

c------------------------------------------------------------------------
c     
c     check if the point falls inside the interpolation volumes
c     
c------------------------------------------------------------------------

*     -----------------------
*     INNER MAP
*     -----------------------
      if(
     $          (x.ge.edgexmin).and.(x.le.edgexmax)
     $     .and.(y.ge.edgeymin).and.(y.le.edgeymax)
     $     .and.(z.ge.edgezmin).and.(z.le.edgezmax)
     $     ) then


        call inter_B_inner(x,y,z,res)
c        print*,'INNER - ',z,res

      endif

*     -----------------------
*     OUTER MAP
*     -----------------------
      if(
     $         ((x.ge.edgeuxmin).and.(x.le.edgeuxmax)
     $     .and.(y.ge.edgeuymin).and.(y.le.edgeuymax)
     $     .and.(z.ge.edgeuzmin).and.(z.le.edgeuzmax))
     $     .or.
     $         ((x.ge.edgelxmin).and.(x.le.edgelxmax)
     $     .and.(y.ge.edgelymin).and.(y.le.edgelymax)
     $     .and.(z.ge.edgelzmin).and.(z.le.edgelzmax))
     $     ) then
         

        call inter_B_outer(x,y,z,res)
c        res(2)=res(2)*10
c        print*,'OUTER - ',z,res

      endif

*     --------------------------------
*     GAP between INNER and OUTER MAPS
*     --------------------------------
      if(
     $          (x.gt.edgexmin).and.(x.lt.edgexmax)
     $     .and.(y.gt.edgeymin).and.(y.lt.edgeymax)
     $     .and.(z.gt.edgezmax).and.(z.lt.edgeuzmin)
     $     )then
         
         zu = edgeuzmin
         zl = edgezmax
         call inter_B_inner(x,y,zl,resu)
         call inter_B_outer(x,y,zu,resl)

         do i=1,3
            res(i) = z  * ((resu(i)-resl(i))/(zu-zl))
     $           + resu(i)
     $           -   zu * ((resu(i)-resl(i))/(zu-zl))
         enddo
c        print*,'GAP U - ',z,res

      elseif(
     $          (x.gt.edgexmin).and.(x.lt.edgexmax)
     $     .and.(y.gt.edgeymin).and.(y.lt.edgeymax)
     $     .and.(z.gt.edgelzmax).and.(z.lt.edgezmin)
     $     ) then
         
        
         zu = edgezmin
         zl = edgelzmax
         call inter_B_inner(x,y,zu,resu)
         call inter_B_outer(x,y,zl,resl)

         
         do i=1,3
            res(i) = z  * ((resu(i)-resl(i))/(zu-zl))
     $           + resu(i)
     $           -   zu * ((resu(i)-resl(i))/(zu-zl))
         enddo
c        print*,'GAP D - ',z,res

      endif


      return
      end


1	cafagna	3.1	*************************************************************************
2			*
3			* Subroutine inter_B.f (from tracker software analysis)
4			*
5			* it computes the magnetic field in a chosen point x,y,z inside or
6			* outside the magnetic cavity, using a trilinear interpolation of
7			* B field measurements (read before by means of ./read_B.f)
8			* if the point falls outside the interpolation volume, set the field to 0
9			*
10			* needs:
11			* - ../common/common_B_inner.f common file for the inner magnetic field map
12			* - ./inter_B_inner.f common file for the inner magnetic field map
13			*
14			* to be called after ./read_B.f (magnetic field map reading subroutine)
15			*
16			* input: coordinates in m
17			* output: magnetic field in T
18			*
19			*************************************************************************
20
21			subroutine inter_B(x,y,z,res) !coordinates in m, magnetic field in T
22			IMPLICIT DOUBLE PRECISION (A-H,O-Z)
23			#include "gpfield.inc"
24
25			c------------------------------------------------------------------------
26			c
27			c local variables
28			c
29			c------------------------------------------------------------------------
30
31			real*8 x,y,z !point of interest
32			real*8 res(3) !interpolated B components: res = (Bx, By, Bz)
33
34	bottai	3.2	real*8 zl,zu
35			real*8 resu(3),resl(3)
36	cafagna	3.1	c------------------------------------------------------------------------
37			c
38			c set the field outside the interpolation volume to be 0
39			c
40			c------------------------------------------------------------------------
41
42			do ip=1,3
43			res(ip)=0.
44			enddo
45
46			c------------------------------------------------------------------------
47			c
48	bottai	3.2	c check if the point falls inside the interpolation volumes
49	cafagna	3.1	c
50			c------------------------------------------------------------------------
51	bottai	3.2
52			* -----------------------
53			* INNER MAP
54			* -----------------------
55			if(
56			$ (x.ge.edgexmin).and.(x.le.edgexmax)
57	cafagna	3.1	$ .and.(y.ge.edgeymin).and.(y.le.edgeymax)
58	bottai	3.2	$ .and.(z.ge.edgezmin).and.(z.le.edgezmax)
59			$ ) then
60
61	cafagna	3.1
62			call inter_B_inner(x,y,z,res)
63	bottai	3.2	c print*,'INNER - ',z,res
64
65			endif
66
67			* -----------------------
68			* OUTER MAP
69			* -----------------------
70			if(
71			$ ((x.ge.edgeuxmin).and.(x.le.edgeuxmax)
72			$ .and.(y.ge.edgeuymin).and.(y.le.edgeuymax)
73			$ .and.(z.ge.edgeuzmin).and.(z.le.edgeuzmax))
74			$ .or.
75			$ ((x.ge.edgelxmin).and.(x.le.edgelxmax)
76			$ .and.(y.ge.edgelymin).and.(y.le.edgelymax)
77			$ .and.(z.ge.edgelzmin).and.(z.le.edgelzmax))
78			$ ) then
79
80
81			call inter_B_outer(x,y,z,res)
82			c res(2)=res(2)*10
83			c print*,'OUTER - ',z,res
84
85			endif
86
87			* --------------------------------
88			* GAP between INNER and OUTER MAPS
89			* --------------------------------
90			if(
91			$ (x.gt.edgexmin).and.(x.lt.edgexmax)
92			$ .and.(y.gt.edgeymin).and.(y.lt.edgeymax)
93			$ .and.(z.gt.edgezmax).and.(z.lt.edgeuzmin)
94			$ )then
95
96			zu = edgeuzmin
97			zl = edgezmax
98			call inter_B_inner(x,y,zl,resu)
99			call inter_B_outer(x,y,zu,resl)
100
101			do i=1,3
102			res(i) = z * ((resu(i)-resl(i))/(zu-zl))
103			$ + resu(i)
104			$ - zu * ((resu(i)-resl(i))/(zu-zl))
105			enddo
106			c print*,'GAP U - ',z,res
107
108			elseif(
109			$ (x.gt.edgexmin).and.(x.lt.edgexmax)
110			$ .and.(y.gt.edgeymin).and.(y.lt.edgeymax)
111			$ .and.(z.gt.edgelzmax).and.(z.lt.edgezmin)
112			$ ) then
113
114
115			zu = edgezmin
116			zl = edgelzmax
117			call inter_B_inner(x,y,zu,resu)
118			call inter_B_outer(x,y,zl,resl)
119
120
121			do i=1,3
122			res(i) = z * ((resu(i)-resl(i))/(zu-zl))
123			$ + resu(i)
124			$ - zu * ((resu(i)-resl(i))/(zu-zl))
125			enddo
126			c print*,'GAP D - ',z,res
127
128	cafagna	3.1	endif
129
130
131			return
132			end
133
134